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Transcript
Advances in the Genetic Diagnosis
of the Cerebellar Ataxias
Brent L. Fogel, M.D., Ph.D.
Associate Professor
UCLA Department of Neurology
Program in Neurogenetics
David Geffen School of Medicine
at UCLA
March 11, 2017
http://esciencecommons.blogspot.com/2011/01/undersea-cables-add-twist-to-dna-study.html
DISCLAIMER
 The information provided by speakers in any
presentation made as part of the 2017 NAF
Annual Ataxia Conference is for informational
use only.
 The NAF encourages all attendees to consult
with their primary care provider, neurologist, or
other health care provider about any advice,
exercise,
therapies, medication, treatment,
nutritional supplement, or regimen that may have
been mentioned as part of any presentation.
 Products or services mentioned during these
presentations does not imply endorsement by
the NAF.
DISCLOSURES
 Dr. Fogel receives funding from the National Institutes of Health.
 Dr. Fogel is employed at an academic medical institution that
offers diagnostic clinical exome sequencing. Dr. Fogel has no
financial relationships related to this testing.
 Dr. Fogel has no personal financial relationships with
commercial interests relevant to this presentation during the
past 12 months to disclose or list.
Ataxia is a symptom…NOT a disease!
Term provides no information on cause, severity, or prognosis
COUGH
Upper respiratory Infection (viral) (“a cold”)
Influenza (viral) (“the flu”)
Pneumonia (bacterial or viral)
Tuberculosis (mycobacterial)
Coccidioidomycosis (fungal) (“Valley Fever”)
Ebola (viral)
The Importance of a Thorough Medical Evaluation:
Many Causes of Cerebellar Ataxia!
Nutritional
Dominant
Endocrine
Metabolic
Recessive
Infectious
Acquired
Causes
Inflammatory
Neoplastic
Genetic
Causes
Mitochondrial
Metabolic
“Familial, Hereditary,
etc.”
X-linked
Paraneoplastic
Autoimmune
Other
Toxic
“Sporadic Ataxia”
Unexpected
No clear family history
…but can be acquired,
genetic, or idiopathic!
Idiopathic
Causes
1 in 5,000 persons
worldwide have ataxia
1 in 10,000 persons
have a genetic ataxia
Neurodegeneration
Diagnostic Reservoirs Hiding Neurogenetic Disease
Shared
Clinical
Phenotype




Cerebral palsy
Intellectual disability
Epilepsy
Movement disorders




Ataxia
Dementia
Multiple sclerosis
Peripheral neuropathy
Diagnosis
Presumed identical or similar cause
Traditional Medical
Approach
Same
Management
for Everyone?
Heterogeneous
Clinical
Phenotype
Diagnosis
Diagnosis
Specific or unique
molecular cause
Precision Health
Approach
Diagnosis
Individualized
Symptomatic
Treatment or
Surveillance
Genetic
Counseling &
Psychosocial
Benefits
Disease
Modification
or Cure
Ataxia is Common in Neurogenetic Disease
More than 680 genes are associated with ataxia
as a primary or secondary symptom*
Total Genes
~ 396
~ 229
~ 46
~ 12
Inheritance
Autosomal Recessive
Autosomal Dominant
X-linked
Mitochondrial
(…and estimates suggest that we currently only know about
half of the genes that cause hereditary ataxia!)
Effective strategies are necessary for optimal clinical evaluation.
*Source: Online Mendelian Inheritance in Man, OMIM®. 11/2016. http://omim.org/
DNA & Genetics - Chromosomes
PATERNAL
MATERNAL
Definitions
Gene = basic unit of inheritance
Chromosome = linear organization of genes
23 pairs of chromosomes (one set each from mother and father)
Genome = all the DNA (chromosomes) within a person
David Adler, University of Washington
DNA & Genetics - Inheritance
The Autosomal Dominant Cerebellar Ataxias
• Commonly referred to as the Spinocerebellar Ataxias (SCAs)
• Phenotype of slowly progressive, clinically heterogeneous ataxia
• Currently 43 distinct clinical forms with 30 identified genes
Fogel and Geschwind,
Neurology in Clinical Practice,
2012
Autosomal Dominant Cerebellar Ataxia
• Adult onset, typically between 20-50 years of age
• Overall ~ 4 cases per 100,000 people worldwide
Most Common
SCA3
SCA1
SCA2
SCA6
SCA7
(~50% of total)
Inherit one
“damaged” copy
of the gene
(from either
mom or dad)
Most Recent
2014
SCA21 (France)
SCA34 (Canada)
SCA38 (Italy)
SCA40 (China)
2015
SCA41 (USA)
SCA42 (France, Japan)
2016
SCA43 (Belgium)
http://ghr.nlm.nih.gov/handbook/illustrations/autodominant
The Autosomal Recessive Cerebellar Ataxias
• New diseases being named Spinocerebellar Ataxia, Recessive (SCARs)
• Slowly progressive often with sensory/sensorimotor polyneuropathy
• Several diseases involve organ systems outside the CNS (biomarkers)
• At least 40 identified genes cause primary recessive ataxia
Fogel and Geschwind,
Neurology in Clinical Practice,
2012
Autosomal Recessive Cerebellar Ataxia
• Onset typically before age 20 years
• Milder variants can present in adulthood
• Overall ~ 4 cases per 100,000 people worldwide
Most Common
Friedreich
ataxia
(~50%)
Inherit two
“damaged”
gene copies
(one from
mom & dad)
http://ghr.nlm.nih.gov/hand
book/illustrations/
autorecessive
Most Recent
2014
SCAR17 (Turkey, Netherlands)
SCAR20 (Portugal, Middle East)
SCAR23 (Ireland, Egypt)
2015
SCAR19 (Turkey)
SCAR21 (Europe, Cuba)
2016
SCAR22 (Japan)
SCAR24 (China)
Genetic Testing – Types of Genetic Testing
Full gene sequencing (Traditional Sanger method)
 Most complete test but also most expensive per gene
 Can potentially discover novel coding mutations
 REMEMBER: Not every sequence change causes disease!
Targeted mutation analysis
 Less expensive, useful in families to detect pre-defined mutations
 REMEMBER: Negative test rules out the specific mutations only!
Repeat expansion testing
 Required for common dominant
SCAs and Friedreich Ataxia
 Cannot identify sequence
changes or other types of
mutations
Genetic Testing – Traditional Gene Panels
Often combine multiple types of testing for several different genes
 Full gene sequencing (Traditional Sanger method)
 Targeted mutation analysis
 Repeat expansion testing
Can be very expensive per gene
 Range US$500 - US$30,000 or more
 Insurance coverage varies
These panels don’t test every ataxia gene
 Not all ataxia genes are known!
 Not all genes have specific tests
 Some genes only cause ataxia
rarely (e.g., not in all patients) so
they aren’t included
Genetic Testing Bias
Should you look at hay by the handful
for anything that might be sharp?
…or should you look through
the whole haystack for the
needle?
Classic Question: Single or Multi-Gene Panel?
Major Caveat to Biased Single Gene or Multi-Gene Panel Testing

Clinical Heterogeneity: The same phenotype common to one
disorder may be an atypical form of another, how do you know?

Genetic Expressivity: Currently documented phenotypes may not
represent the only forms of disease caused by a gene.
Examples:
- Late-onset Friedreich Ataxia (up to 25% of cases)
- Fragile X-Syndrome & Fragile X-Tremor/Ataxia Syndrome (premutation)
- Adult Polyglucosan Body Disease & Glycogen Storage Disease Type IV
- X-linked Adrenoleukodystrophy & Adrenomyeloneuropathy
- AOA2 (ataxia & polyneuropathy) vs. ALS4 (motor neuron)
How can one minimize such confounders
and maximize genetic testing efficacy?
Exome Sequencing: An Unbiased Tool for Diagnosis
Genome
3.3 x 109 base pairs
~20,000 genes
Exome
~1% of genome
~3 x 107 base pairs
~20,000 genes
Examination of
every gene
simultaneously
provides an
unbiased method
of genetic testing
~26% overall
diagnostic rate
(~3,000 neurologic cases)
http://www.genome.gov/dmd/index.cfm?node=Photos/Graphics
The Rise of Exome Sequencing in the Diagnosis of Ataxia
Introduction of
Clinical Exome
Sequencing
When to Use Exome Sequencing in Ataxia?
Most Ataxia Patients, Often Sporadic
Often Familial
20-40%*
40-50%*
*Patients with
negative workup for acquired
causes and
common
genetic causes
Pritchard DJ & Korf BR 2003 Medical Genetics at a Glance
Types of Next-Generation Genetic Testing
Whole Exome (sometimes called a “Clinical Exome”)
 Most complete test, covers all ~20,000 genes in the genome
 Most expensive overall (~$5-10K) but least expensive per gene
Next-Generation Panels
(sometimes called “Exome Panels” or even a “Clinical Exome”)
 Less expensive per gene than traditional Sanger panels
 Includes only a few to hundreds of genes depending on the test
 Some laboratories may offer reflex option to whole exome if negative
REMEMBER!
 Different laboratories may analyze and/or report results differently
 Method does not detect repeat expansion disorders
 Not every sequence change causes disease
Which Type of Next-Gen Sequencing Test is Best for Ataxia?
Redefining Phenotypes to Improve Diagnosis
Hereditary Spastic Paraplegia (HSP)
• Class of disorders characterized by progressive weakness and
spasticity of the legs
• Prevalence roughly equal to Spinocerebellar Ataxia worldwide
• Genes designated as Spastic Paraplegia (SPG), now up to SPG77
SPG7
• Causes up to 12% of all recessive HSPs worldwide
• SPG7 has been identified in ataxia patients in several whole exome studies
• 39% (12/31) families in study of spastic ataxia in Canada (Choquet et al. 2015)
PNPLA6/SPG39
• Identified in 2008 in patients with spastic paraplegia
• In 2014 the SPG39 gene was found to cause forms of cerebellar ataxia
including syndromes with visual and/or hormonal problems (Synofzik et al. 2014)
- Boucher-Neuhäuser syndrome
- Gordon Holmes syndrome
- Laurence-Moon syndrome
Discovering New Genetic Disorders
•
•
•
•
•
40 year old white man of European ancestry
2 years progressive imbalance and ataxic gait
Negative evaluation for acquired causes of ataxia
MRI with mild cerebellar vermian atrophy
No family history but estranged from paternal side
Sagittal T1 magnetic resonance
imaging of the brain shows very
mild atrophy of the cerebellar
vermis (arrow) with no brainstem
involvement.
TRPC3
• TRPC3 is a non-selective cation channel linked to key signaling pathways
affected in cerebellar ataxia
SCA41
Role of TRPC3 in the mGluR1 signaling pathway essential for Purkinje cell function.
Loss of any component in the depicted signaling cascade results in cerebellar ataxia in
humans and/or mice.
Figure reproduced from Becker EB. Cerebellum 2015.
Rapid Identification of Treatable Patients
Clinical History
• 9 year old Lebanese girl with progressive balance problem since age 2 years
• Gait & limb ataxia, sensory neuropathy, areflexia and upgoing toes
• Scoliosis but no skin, cardiac, or muscle involvement
• Detailed genetic testing negative
• Exome sequencing identified homozygous mutations in SLC52A2
• SLC52A2 encodes a membrane-bound riboflavin transport protein
• Mutation of SLC52A2 causes Brown-Vialetto-Van Laere syndrome
(juvenile-onset motor neuron disease, deafness, ataxia)
• Disease is typically fatal in 1st decade of life
• Identical mutation reported in classic BVVLS in 2 families (one from Lebanon)
Rapid Identification of Treatable Patients
Follow-Up
• Patient diagnosed with Brown-Vialetto-Van Laere syndrome
• Riboflavin transporter is defective but not absent, therefore could potentially
drive uptake with high dose intake of riboflavin
Treatment started immediately and symptoms stabilized.
Exercise and physical therapy led to marked improvements.
Now stabile for over 4 years.
Mildly clumsy but playing volleyball, dancing, karate, running
long distance.
SHE IS ESSENTIALLY CURED.
Clinical Evaluation
Detailed History of Symptoms
Comprehensive Neurological Examination
Complete Family History
MRI of the Brain
Most common etiologies
Diagnostic Evaluation
Screen for Acquired Causes of Ataxia
Genetic etiologies
Common Genes:
Estimated 40-50%
of Genetic Ataxia
Basic Diagnostic: Initial Genetic Screening
Single Gene Testing*
Repeat Expansion Disorders
Dominant: SCA1, SCA2, SCA3, SCA6, SCA7
Recessive: FRDA
If negative
Advanced Diagnostic: Clinical Exome Sequencing
Rare Genes:
If onset prior to age 20 years or suspected recessive
Estimated <1%
of Genetic Ataxia inheritance consider simultaneous evaluation of parents.
Reasons to Diagnose Neurogenetic Disease
Can be decades (or never) for rare diseases
Diagnosis
Disease Pathogenesis
Begins
Time to Diagnosis
Neurological
Disability
or Death
Time
Clinical Onset of
Symptoms
Causal
Agent
Induction Period
Comes to Medical
Attention
Preclinical Period
Disease Progression
Latent Period
Establishing a genetic cause stops
nonproductive search for other causes
• Disease or its comorbidities
may be modifiable
• Genetic counseling
Modified from Nelson, Tanner, Van Den Eeden, McGuire eds: Neuroepidemiology, 2004
Present
The Future of Clinical Genetic Testing
• Clinical Exome Sequencing is an unbiased form of genomic testing that
assesses all 20,000 genes in the human genome simultaneously
(cheap and efficient)
• Clinical Exome Sequencing improves diagnosis of clinically heterogeneous
neurogenetic phenotypes (broad application)
• Clinical Exome Sequencing can lead to diagnoses that directly affect and
improve patient management (clinically meaningful)
• Clinical Exome Sequencing reduces time to diagnosis sparing patients an
extensive diagnostic odyssey (and sparing payers the subsequent costs)
• Clinical Exome Sequencing should compliment, not
replace, a systematic patient evaluation (including
high yield genetic testing if appropriate)
• Because results are not typically “positive” or “negative”
physicians must receive training in the proper use and
interpretation of clinical exome sequencing
(disease-specific interpretation)
Acknowledgements
Our Patients and their Families
Web: http://fogellab.neurology.ucla.edu/
Twitter: @fogellab
UCLA Neurology
UCLA Neurogenetics
UCLA Molecular Diagnostics Laboratory
National Institutes of Health
National Ataxia Foundation
Questions?
Image from Anatomography maintained by Life Science Databases(LSDB).
From http://commons.wikimedia.org/wiki/File:Cerebellum_small.gif